Disentangling acute motor deficits and adaptive responses evoked by the loss of cerebellar output.

IF 6.4 1区生物学 Q1 BIOLOGY

eLife Pub Date : 2025-06-25 DOI:10.7554/eLife.105152

Nirvik Sinha, Sharon Israely, Ora Ben Harosh, Ran Harel, Julius P A Dewald, Yifat Prut

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Abstract

Patients with cerebellar damage experience various motor impairments, but the specific sequence of primary and compensatory processes that contribute to these deficits remains unclear. To clarify this, we reversibly blocked cerebellar outflow in monkeys engaged in planar reaching tasks. This intervention led to a spatially selective reduction in hand velocity, primarily due to decreased muscle torque, especially in movements requiring high inter-joint torque coupling. When examining repeated reaches to the same target, we found that the reduced velocity resulted from both an immediate deficit and a gradually developing compensatory slowing to reduce passive inter-joint interactions. However, the slowed hand velocity did not account for the fragmented and variable movement trajectories observed during the cerebellar block. Our findings indicate that cerebellar impairment results in motor deficits due to both inadequate muscle torque and an altered motor control strategy for managing impaired limb dynamics. Additionally, impaired motor control elevates noise, which cannot be entirely mitigated through compensatory strategies.

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解开小脑输出缺失引起的急性运动缺陷和适应性反应。

小脑损伤患者会经历各种运动障碍，但导致这些缺陷的主要和代偿过程的具体顺序尚不清楚。为了澄清这一点，我们可逆地阻断了从事平面到达任务的猴子的小脑流出。这种干预导致了手速度的空间选择性降低，主要是由于肌肉扭矩降低，特别是在需要高关节间扭矩耦合的运动中。当检查到同一目标的重复到达时，我们发现速度降低是由直接赤字和逐渐发展的代偿性减速造成的，以减少被动关节间的相互作用。然而，减慢的手速度并不能解释在小脑阻滞期间观察到的碎片化和可变的运动轨迹。我们的研究结果表明，由于肌肉扭矩不足和控制肢体动力学受损的运动控制策略改变，小脑损伤导致运动缺陷。此外，受损的运动控制会提高噪音，这不能通过补偿策略完全减轻。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

eLife BIOLOGY-

CiteScore

12.90

自引率

3.90%

发文量

3122

审稿时长

17 weeks

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